Positive selection for loss-of-function tat mutations identifies critical residues required for TatA activity

The Tat system, found in the cytoplasmic membrane of many bacteria, is a general export pathway for folded proteins. Here we describe the development of a method, based on the transport of chloramphenicol acetyltransferase, that allows positive selection of mutants defective in Tat function. We have demonstrated the utility of this method by selecting novel loss-of-function alleles of tatA from a pool of random tatA mutations. Most of the mutations that were isolated fall in the amphipathic region of TatA, emphasizing the pivotal role that this part of the protein plays in TatA function.     

Genetic Control of the Transport of Hexose Phosphates in Escherichia coli: Mapping of the uhp Locus

A number of mutations affecting the transport of hexose phosphates in Escherichia coli were ordered within the uhp locus. Three-point crosses by transduction or conjugation allowed the ordering of the alleles relative to the adjacent pyrE marker. The same linear map was obtained by both methods. This, combined with the regulatory properties of revertants of these mutants, allowed a tentative identification of two genes, one presumably coding for the transport system (uhpT) and the other(s) specifying a regulatory element (uhpR). The order of these is pyrE-uhpT-uhpR. Mutants exhibiting constitutive expression of the transport system were isolated. This behavior is genetically linked to the uhp locus, but more precise localization was not possible.     

Isolation and characterization of hexose transport mutants in L6 rat myoblasts

A method for the selection and isolation of hexose transport mutants in undifferentiated rat myoblast L6 cells is reported; 2-deoxy-D-glucose (2-DOG)-and 2-deoxy-2-fluoro-D-glucose (2FG)-resistant mutants were selected after mutagenization of L6 cells with ethyl methanesulfonate. Of these, D18 and D23 (selected with 0.1 mM 2-DOG) and F72 and F76 (selected with 0.1 mM 2FG) exhibited the lowest hexose transport activity. Uptake of 0.06 mM 2-DOG, 2FG, or 3-O-methyl-D-glucose (3-OMG) by mutants grown in fructose medium supplemented with 0.05 mM 2FG was about four- to five-fold lower than the parental L6 cells. These mutants contain normal levels of ATP and glycolytic enzyme activities. They also exhibit normal transport activities for alpha-aminoisobutyric acid and fructose. Furthermore, hexose transport was observed to be decreased in plasma membrane vesicles prepared from these mutants. Kinetic analysis of 2-DOG and 3-OMG transport in mutant F72 demonstrated that the Vmax for 2-DOG uptake was significantly reduced, whereas the Vmax for 3-OMG transport was not affected. In all cases, the affinity for these hexose analogues was unaffected. In addition mutant F72 was found to be only slightly affected by treatment with various energy inhibitors and sulfhydryl reagents. The results suggest that this mutant is defective in, or has low levels of, a plasma membrane component(s) involved in the high-affinity hexose transport system.     

Approaches used to examine the mechanism and regulation of hexose transport in rat myoblasts

This review discusses some of the approaches and general criteria that we have used to examine the properties of the hexose transport system in undifferentiated L6 rat myoblasts. These approaches include studying the kinetics of hexose transport in whole cells and plasma membrane vesicles, the effects of various inhibitors on hexose transport, the isolation and characterization of hexose transport mutants, and the use of cytochalasin B (CB) to identify the transport component(s). Transport kinetics indicated that two transport systems are present in these cells. 2-Deoxy-D-glucose is transported primarily by the high affinity system, whereas 3-O-methyl-D-glucose is transported by the low affinity system. Furthermore, these two transport systems are inactivated to different extents by CB. CB has a higher binding affinity for the low affinity hexose transport system. The inhibitory effect of various hexose analogues also revealed the presence of two hexose transport systems. The effects of various ionophores and energy uncouplers on hexose transport suggest that the high affinity system is an active transport process, whereas the low affinity system is of the facilitated diffusion type. The high affinity system is also sensitive to sulfhydryl reagents, whereas the low affinity system is not. Further evidence for the presence of two transport systems comes from the characterization of hexose transport mutants. Two of the mutants isolated are shown to be defective in the high affinity transport system, but not in the low affinity transport system. These mutants are also defective in the CB low affinity binding site. Based on our results a tentative working model for hexose transport in L6 rat myoblasts is presented.     

Genetic characterization and regulation of the nadB locus of Salmonella typhimurium.

The nadB locus encodes the first enzyme of NAD synthesis. It has been reported that this gene and nadA are regulated by a positive regulatory protein encoded in the nadB region. In pursuing this regulatory mechanism, we constructed a fine-structure genetic map of the nadB gene. The region appears to include a single complementation group; no evidence for a positive regulatory element was found. Several mutations causing resistance to the analog 6-aminonicotinamide mapped within the structural gene and probably cause resistance to feedback inhibition. Regulatory mutations for nadB were isolated. These mutants mapped far from nadB near the pnuA gene, which encodes a function required for nicotinamide mononucleotide transport. The regulatory mutations appear to affect a distinct function encoded in the same operon as pnuA.     

Genetics and regulation of D-xylose utilization in Salmonella typhimurium LT2.

Twenty-one Xyl- mutants of Salmonella typhimurium were selected: all had lost one or more of the activities for D-xylose isomerase, C-xylulokinase, or D-xylose transport. The mutants were classified into five functional groups: xylR, pleiotropic negative (12 mutants); xylA, D-xylose isomerase defective (3 mutants); xylB, D-xylulokinase defective (2 mutants); xylT, D-xylose transport defective (1 mutant); and 3 mutants with defective D-xylose isomerase and D-xylulokinase. Some nonsense mutations were identified among the xylR mutants. Two F'xyl plasmids were isolated by selection for early transfer of xyl+ by an Hfr which transfers xyl as a terminal gene; a plasmid with a mutation in the xyl genes, F'xylR1, was also isolated. Complementation tests using F'xyl plasmids indicate that expression of the xylA, xylB, and xylT genes is under the positive control of the xylR regulatory gene. Conjugation crosses and P22-mediated transduction data indicate that all the xyl mutations tested are in a cluster of genes at 78 units on the linkage map, and that the gene order is xylT--xylR--xylB--xylA--glyS--mtlA,D.     

Utilization of orotate as a pyrimidine source by Salmonella typhimurium and Escherichia coli requires the dicarboxylate transport protein encoded by dctA.

Mutants deficient in orotate utilization (initially termed out mutants) were isolated by selection for resistance to 5-fluoroorotate (FOA), and the mutations of 12 independently obtained isolates were found to map at 79 to 80 min on the Salmonella typhimurium chromosome. A gene complementing the mutations was cloned and sequenced and found to possess extensive sequence identity to characterized genes for C4-dicarboxylate transport (dctA) in Rhizobium species and to the sequence inferred to be the dctA gene of Escherichia coli. The mutants were unable to utilize succinate, malate, or fumarate as sole carbon source, an expected phenotype of dctA mutants, and introduction of the cloned DNA resulted in restoration of both C4-dicarboxylate and orotate utilization. Further, succinate was found to compete with orotate for entry into the cell. The S. typhimurium dctA gene encodes a highly hydrophobic polypeptide of 45.4 kDa, and the polypeptide was found to be enriched in the membrane fraction of minicells harboring a dctA+ plasmid. The DNA immediately upstream of the deduced -35 region contains a putative cyclic AMP-cyclic AMP receptor protein complex binding site, thus affording an explanation for the more effective utilization of orotate with glycerol than with glucose as carbon source. The E. coli dctA gene was cloned from a lambda vector and shown to complement C4-dicarboxylate and orotate utilization in FOA-resistant mutants of both E. coli and S. typhimurium. The accumulated results demonstrate that the dctA gene product, in addition to transporting C4-dicarboxylates, mediates the transport of orotate, a cyclic monocarboxylate.     

Fine-structure genetic map of the maltose transport operon of Salmonella typhimurium.

We have constructed a fine-structure genetic map of the maltose transport operon in Salmonella typhimurium. We have isolated mal mutants by using indicator plates, penicillin selection, or a proton suicide technique. Mutants were obtained as spontaneous events or were induced by chemical mutagenesis and transposon insertion. Tn10 and Mu d(lac Ap)1 insertion mutations were used to create deletions. Mutations were also obtained in a gene that is equivalent to lamB in Escherichia coli, which codes for the lambda bacteriophage receptor. The gene products in the mutants were characterized by sodium dodecyl sulfate-polyacrylamide-gel electrophoresis and immunoblotting. Our data indicate that the location of this operon on the Salmonella chromosome as well as the gene order and its orientation are the same as those in E. coli. This map will be useful in studying the mechanism of periplasmic transport in S. typhimurium.     

Transport of vitamin B12 in Escherichia coli: cloning of the btuCD region.

The transport of vitamin B12 in Escherichia coli requires a specific vitamin B12 receptor protein in the outer membrane and the tonB gene product. In addition, the btuC gene, located at min 38 on the genetic map, has been found to influence vitamin B12 uptake or utilization. The btuC function is required for the growth response to vitamin B12 when the outer membrane transport process (btuB or tonB function) is defective. However, even in a wild-type strain, btuC is required for proper transport of vitamin B12. Additional mutations in the vicinity of btuC were isolated as lac fusions that produced a phenotype similar to that of a btuC mutant. The btuC region was cloned by selection for complementation of a btuC mutation. Complementation testing with plasmids carrying various deletions or transposon Tn1000 insertions demonstrated that the new mutations defined a separate, independently expressed locus, termed btuD. The coding regions for both genes were identified on a 3.4-kilobase HindIII-HincII fragment and were 800 to 1,000 base pairs in length. They were separated by a 600- to 800-base-pair region. The gene order in this portion of the chromosome map was found to be pps-zdh-3::Tn10-btuD-btuC-pheS. Expression of beta-galactosidase in the btuD-lac fusion-bearing strains, whether proficient or defective in vitamin B12 transport, was not regulated by the presence of vitamin B12 in the growth medium.     

Genetic analysis of the Pseudomonas aeruginosa PAO high-affinity branched-chain amino acid transport system by use of plasmids carrying the bra genes.

About 30 mutants of Pseudomonas aeruginosa PAO defective in the high-affinity branched-chain amino acid transport system (LIV-I) were isolated by the selection for resistance to 4-aza-DL-leucine, a toxic leucine analog for LIV-I. All of the mutants were complemented by plasmid pKTH24, harboring the braC gene, which encodes the branched-chain amino acid-binding protein, and the four open reading frames named braD, braE, braF, and braG (T. Hoshino and K. Kose, J. Bacteriol. 172:5531-5539, 1990). We identified five cistrons corresponding to these bra genes by complementation analysis with various derivatives of pKTH24, confirming that the braD, braE, braF, and braG genes are required for the LIV-I transport system. We also found mutations that seem likely to be mutations in a promoter region for the bra genes and those with polarity in the intercistronic region between braC and braD. Analysis with an omega interposon showed that the bra genes are organized as an operon and are cotranscribed in the order braC-braD-braE-braF-braG from a promoter located in the 5'-flanking region of the braC gene.     

Genetic evidence for substrate and periplasmic-binding-protein recognition by the MalF and MalG proteins, cytoplasmic membrane components of the Escherichia coli maltose transport system

We isolated mutants of Escherichia coli in which the maltose-binding protein (MBP) is no longer required for growth on maltose as the sole source of carbon and energy. These mutants were selected as Mal+ revertants of a strain which carries a deletion of the MBP structural gene, malE. In one class of these mutants, maltose is transported into the cell independently of MBP by the remaining components of the maltose system. The mutations in these strains map in either malF or malG. These genes code for two of the cytoplasmic membrane components of the maltose transport system. In some of the mutants, MBP actually inhibits maltose transport. We demonstrate that these mutants still transport maltose actively and in a stereospecific manner. These results suggest that the malF and malG mutations result in exposure of a substrate recognition site that is usually available only to substrates bound to MBP.     

A genetic locus for the GltII-glutamate transport system in Escherichia coli

Growth of Escherichia coli on glutamate as sole carbon source only occurs in strains carrying mutations that increase the expression of genes encoding glutamate transport systems. From an analysis of mutants able to grow on glutamate we have identified a genetic locus that when mutated elevates the expression of the GltII glutamate/aspartate transport system. The mutants exhibit increased sensitivity to the toxic aspartate analogues cysteate and DL-threo-beta-hydroxyaspartate. Data from the analysis of mutants that are impaired in this transport activity are consistent with the presence of the structural gene for the transport system at the same genetic locus. The locus was mapped by P1 transduction to a region of the E. coli chromosome lying at approximately 92.5 min on the E. coli genetic map.     

Fosfomycin resistance: selection method for internal and extended deletions of the phosphoenolpyruvate:sugar phosphotransferase genes of Salmonella typhimurium.

Selection for resistance to the antibiotic fosfomycin (FOS; L-cis 1,2-epoxypropylphosphonic acid, a structural analogue of phosphoenolpyruvate) was used to isolate mutants carrying internal and extended deletions of varying lengths within the ptsHI operon of Salmonella typhimurium. Strains carrying "tight" ptsI point mutations and all mutants in which some or all of the ptsI gene was deleted were FOS resistant. In contrast, strains carrying ptsH point mutations were sensitive to FOS. Resistance to FOS appeared to result indirectly from catabolite repression of an FOS transport system, probably the sn-glycerol-3-phosphate transport system. Resistant ptsI mutants became sensitive to FOS when grown on D-glucose-6-phosphate, which induces an alternate transport system for FOS, or when grown in the presence of cyclic adenosine 3',5'-monophosphate. A detailed fine-structure map of the pts gene region is presented.     

Isolation of catalase-deficient Escherichia coli mutants and genetic mapping of katE, a locus that affects catalase activity

A number of catalase-deficient mutants of Escherichia coli which exhibit no assayable catalase activity were isolated. The only physiological difference between the catalase mutants and their parents was a 50- to 60-fold greater sensitivity to killing by hydrogen peroxide. For comparison, mutations in the xthA and recA genes of the same strains increased the sensitivity of the mutants to hydrogen peroxide by seven- and fivefold, respectively, showing that catalase was the primary defense against hydrogen peroxide. One class of mutants named katE was localized between pfkB and xthA at 37.8 min on the E. coli genome. A second class of catalase mutants was found which did not map in this region.     

Genetic studies of mutants in a high-affinity methionine transport system in Salmonella typhimurium

Summary A total of 30 metP mutations defective in the high-affinity methionine transport system were linked in P1 transduction to the zaf-1351::Tn10 insertion mutation at min 5–6 on the Salmonella typhimurium chromosome map. The relationship of metP to several other markers in this region was studied. Methionine transport was strongly inhibited by arsenate, suggesting that the metP system belongs to the shock-sensitive category and possesses a periplasmic binding protein. However, other experiments provided less clear cut evidence. Transport activity was only slightly reduced by osmotic shock; a methionine binding activity was detected in shock fluids from the wildtype strain, and although this activity was reduced by 50% in 3 frameshift mutants, mutants without any activity were not found. No differences were detected in the shock fluids of the 30 mutants when examined by SDS-polyacrylamide gel electrophoresis.     

Fine-structure map of the histidine transport genes in Salmonella typhimurium.

Afine-structure genetic map of the histidine transport region of the Salmonella typhimurium chromosome was constructed. Twenty-five deletion mutants were isolated and used for dividing the hisJ and hisP genes into 8 and 13 regions respectively. A total of 308 mutations, spontaneous and mutagen induced, have been placed in these regions by deletion mapping. The histidine transport operon is presumed to be constituted of genes dhuA, hisJ, and hisP, and the regulation of the hosP and hisJ genes by dhuA is discussed. The orientation of this operon relative to purF has been established by three-point crosses as being: purF duhA hisJ hisP.     

Mapping of insertion mutations in gnd of Escherichia coli with deletions defining the ends of the gene.

A genetic map was prepared for gnd, the gene of Escherichia coli which encodes the metabolically regulated 6-phosphogluconate dehydrogenase. Direct selection methods were used for the isolation of mutants with deletions that define the respective ends of gnd. These selections depended on the availability of a defective lysogen in which gnd was present on a lambda h80 dgnd his prophage located at the att phi 80 region of the chromosome. Mutants with deletions entering gnd from the his-distal end were selected as Gnd- TonB- mutants. Mutants with his-proximal gnd deletions were selected as Gnd-, temperature-resistant mutants of a specially prepared stable lysogen. Gnd- mutants were also isolated after mutagenesis with bacteriophage Mu cts61, and genetic tests were used to determine which mutants carry a Mu cts61 prophage in gnd. The deletion mutations were mapped against each other and against the insertion mutations through the use of F' merodiploid strains. The insertion mutations mapped at seven distinct sites in gnd; three mapped under the deletions defining the his-proximal portion of the gene and three mapped with the his-distal deletions.     

Mapping of mutations associated with neurovirulence in monkeys infected with Sabin 1 poliovirus revertants selected at high temperature.

Poliovirus type 1 neurovirulence is difficult to analyze because of the 56 mutations which differentiate the neurovirulent Mahoney strain from the attenuated Sabin strain. We have isolated four neurovirulent mutants which differ from the temperature-sensitive parental Sabin 1 strain by only a few mutations, using selection for temperature resistance: mutant S(1)37C1 was isolated at 37.5 degrees C, S(1)38C5 was isolated at 38.5 degrees C, and S(1)39C6 and S(1)39C10 were isolated at 39.5 degrees C. All four mutants had a positive reproductive capacity at supraoptimal temperature (Rct+ phenotype). Mutant S(1)37C1 induced paralysis in two of four cynomolgus monkeys, and the three other mutants induced paralysis in four of four monkeys. The lesion score increased from the S(1)37C1 mutant to the S(1)39 mutants. To map the mutations associated with thermoresistance and neurovirulence, we sequenced all regions in which the Sabin 1 genome differs from the Mahoney genome. The S(1)37C1 mutant had one mutation in the 5' noncoding region and another in the 3' noncoding region. Mutant S(1)38C5 had these mutations plus another mutation in the 3D polymerase gene. The S(1)39 mutants had three additional mutations in the capsid protein region. The mutations were located at positions at which the Sabin 1 and Mahoney genomes differ, except for the mutation in the 5' noncoding region. The noncoding-region mutations apparently confer a low degree of neurovirulence. The 3D polymerase mutation, which distinguishes S(1)38C5 and S(1)39 mutants from S(1)37C1, is probably responsible for the high neurovirulence of S(1)38C5 and S(1)39 mutants. The capsid region mutations may contribute to the neurovirulence of the S(1)39 mutants, which was the highest among the mutants.     

High-affinity arabinose transport mutants of Escherichia coli: isolation and gene location.

The gene araF, the product of which is the L-arabinose-binding protein--a component of the high-affinity L-arabinose transport system, was located on the Escherichia coli linkage map at 45 min. We established this location using bacteriophage P2 eductates and bacteriophage P1 cotransduction frequencies with the adjacent genetic loci, his (histidine biosynthesis) and mgl (methylgalactoside transport). In addition, we isolated a number of mutants that phenotypically exhibited altered high-affinity L-arabinose transport capacities. At least two of these mutations were located in the araF gene, as binding protein purified from these strains exhibited altered in vitro arabinose-binding properties.